Psychopharmacology of schizophrenia and other psychotic … · 2011. 6. 19. · Glutamate...
Transcript of Psychopharmacology of schizophrenia and other psychotic … · 2011. 6. 19. · Glutamate...
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Psychopharmacology of schizophrenia and other
psychotic disordersPaul Glue
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Scope
• Pharmacological theories of schizophrenia and psychotic disorders
• Pharmacology of antipsychotic treatments• Treatment strategies for schizophrenia and
psychoses
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Psychosis
• Syndrome (mixture of symptoms) that may occur in many different disorders– delusions, hallucinations, distorted reality testing, abnormal speech and behavior,
motor disturbances– paranoid, excited/disorganised or depressive
• Defining feature of schizophrenia, schizoaffective disorder, drug-induced psychotic disorder, etc
• May occur in mania, depression, dementias (Alzheimer’s; Parkinson’s)
• All treatments based on efficacy in schizophrenic patients, but also effective in psychotic symptoms in other disorders – may not be approved by Medsafe for these indications
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Key Neurotransmitters in Psychosis
• Dopamine
• Glutamate/glycine
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Dopamine Pathways in the Brain
Substantia nigra (A9)(nigrostriatal pathway)
Caudate/Putamen (Striatum)
OlfactoryTubercle
Hypothalamus(tuberoinfundibular pathway)
Cingulate cortex
Ventral tegmentum (A10)(mesolimbic pathway)
Nucleus Accumbens
Amygdala
Frontal cortex
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Schizophrenia and Dopamine• Symptoms: delusions; hallucinations; disturbances of thought; bizarre
behavior; personality change; apathy; withdrawal; etc; episodic or progressive patterns
• Rates: peak onset in late teens-early 30’s; ~ 1% lifetime prevalence• Pathophysiology:
– mesolimbic dopaminergic dysfunction/overactivity (hypothesized)• cocaine/amphetamine produce psychotic
symptoms• Psychotogenic effects at lower doses
than controls • increased DA release relative to controls
(no differences in brain DA concs, DA receptor density, etc.)
• Treatment: – All effective drugs are dopamine D2
antagonists (+ other pharmacological effects); potency correlates with daily dose
• Side effects: – Tremor, stiffness; restlessness; akathisia
Laruelle M, Biol Psych 1999
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Parkinson’s Disease and Dopamine• Symptoms:
– tremor; rigidity/stiffness; slowing of movements; hypokinesia; postural changes;
• Rates – onset in 50’s; highest in elderly; protracted course with high disability/morbidity
• Pathophysiology: – loss of nigrostriatal dopaminergic neurons
• MPTP (DA neurotoxin) produces PD
• Treatment: – Increase synaptic dopamine concentrations – (L-DOPA; DA agonists; inhibitors of MAO-B and COMT)– gradual loss of efficacy over time
• Side effects of treatment: – Dyskinesia; psychosis; hyperprolactinemia/galactorrhea
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Dopaminergic Effects/Side Effects• Drugs that increase DA neurotransmission (↑ synaptic DA)
• most are effective symptomatic treatments for PD• may precipitate/worsen psychosis/dyskinesia• potentially addictive• other s/e: nausea, GI symptoms
– Postsynaptic agonists (DA from L-DOPA; bromocriptine, pramipexole) – Inhibitors of enzymes which degrade DA (MAOIs (selective MAO-B-I: deprenyl); COMT
inhibitors (entocapone) – Inhibitors of DA reuptake or inducers of DA release (cocaine, d-amphetamine - not yet shown
to help PD)
• Block DA neurotransmission (postsynaptic antagonism)• worsen PD; may induce reversible Parkinsonian sx• improve psychotic symptoms• antiemetic, prokinetic
– Typical neuroleptics - D2 antagonists (haloperidol etc plus newer agents)– Atypical neuroleptics (D2 antagonism + ?: clozapine)
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Glutamate hypothesis of schizophrenia
Several genes associated with schizophrenia may affect glutamate receptors
Dysbindin, DISC-1, neuregulin– These proteins help to promote long term
potentiation and improve efficiency of neurotransmission
– Underactivity of these genes could lead to elimination of “weak” glutamate synapses during brain maturation
– DISC-1 also affects transport of synaptic vesicles into presynaptic terminals
– Dysbindin also affects activity of vesicular transporter for Glu
D-amino acid oxidase activator (DAOA)– Alters activity of enzyme that metabolizes
D-serine (endogenous ligand)RSG4 (regulator of G-protein signaling 4)– Affects mGluR signalling via G-proteins
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Glutamate theory• N-methyl-D-aspartate (NMDA) glutamate receptors
– Observation: antagonists (PCP; ketamine) produce schizophrenia-like psychotic symptoms in healthy volunteers (adults but not children); precipitate acute relapse in schizophrenic patients
– Theory: glutamatergic hypofunction in schizophrenia leads to dysregulation of other systems (DA, others)
– Treatment trials:• direct agonist: glutamate - neurotoxic; not possible to administer
• indirect/modulatory agonists: glycine (full agonist); D-cycloserine (partial agonist)• D-cycloserine in combination with typical antipsychotics improves negative and
cognitive symptoms (no change in positive symptoms)• D-cycloserine plus clozapine (atypical) - worsening of negative symptoms
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History of antipsychotic drugs• 1952 - Laborit/Delay and Deniker: chlorpromazine • 1950’s-60’s
– haloperidol, thioridazine, fluphenazine, thiothixine, many others– all have similar antipsychotic efficacy; differ in terms of potency and side effect profile (EPSE liability,
sedation; increased prolactin etc)
• 1960’s– clozapine (atypical antipsychotic)– greater antipsychotic efficacy; no EPSE or hyperprolactinemia; agranulocytocysis– 1988: positive Kane study in treatment-resistant schizophrenia
• 1970’s - relationship between D2 affinity and average daily dose reported • 1990’s
– newer atypicals - risperidone, olanzapine, quetiapine, ziprasidone, aripiprazole– antipsychotic efficacy = haloperidol– EPSE/prolactin increase < haloperidol– ? selective targeting of A10 (VTA) vs A9 (SN) DA neurons
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Typical vs Atypical Antipsychotics• Typical antipsychotic drugs
– Prolactin elevation and extrapyramidal side effects (EPS) were characteristic side effect (e.g. haloperidol)
– EPS: parkinsonism, akathisia, dystonia; were thought to be inextricably linked with antipsychotic efficacy
• Atypical antipsychotic drugs– clozapine: antipsychotic without associated EPS or increases in serum prolactin; active
at low levels of D2 occupancy (
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Pharmacological Profiles and Side Effects (1)
• All antipsychotics have some degree of D2 antagonism– D2 antagonist potency predicts efficacy, daily dose, and liability
for EPSE and hyperprolactinemia– D2 occupancy for efficacy: 60-70%; >80% for EPSE
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Relationship between D2 antagonist potency and average daily dose
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Pharmacological Profiles and Side Effects (2)• Other pharmacology
– antagonism of multiple non-DA receptors– accounts for key side effect profile
• α1 antagonism - postural hypotension, dizziness• M1 antagonism - dry mouth, constipation, blurred vision• H1 antagonism - sedation, weight gain
• Theories of pharmacology of atypicals– ?ratio of 5HT2:D2 antagonism (>1) may reduce EPSE liability,
reduce prolactin secretion– ?low affinity and fast dissociation of drug from D2 receptor may
predict atypicality
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5HT-DA Antagonism Theory (Meltzer)Psychopharm Bull 1989, 25:390
-Typical antipsychotics ( ) have lower affinity for 5HT2a receptors than D2 receptors (5HT2a/D2 ratio 1)
Issues: - Some atypicals (remoxipride) and typicals (loxapine) misclassified by this approach- Pure 5HT2a blockade is not antipsychotic
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Log Ki 5HT2a/D2
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Fast-Off D2 Theory (Seeman)Am J Psych 2001, 158:360
-Typical antipsychotics ( ) bind more tightly to, and dissociate more slowly from, D2 receptors in their high affinity state (dissociation constants (Kd) < natural ligand, DA)- Atypical antipsychotics ( ) bind more loosely to, and dissociate more rapidly from D2 receptors (Kd >DA) - may allow greater responsiveness to changes in endogenous phasic DA signalling
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Aripiprazole• Novel MoA• Complex pharmacology - antagonist/partial agonist effects at D2Rs (effects may be greater with ↑ DA tone)
– also antagonist at 5HT2a and partial agonist at 5HT1a receptors – metabolite (DM-1451) antagonist is a pure D2 antagonist
– older small trials using apomorphine and (-)3-PPP showed improvement in (+) symptoms; however low intrinsic agonist activity probably desirable
• Recent 4wk trial shows efficacy of 15-30mg/day = haloperidol 10mg/day; main unique adverse events: nausea and vomiting; low liability for EPSE and no prolactin elevation (J Clin Psych 2002, 63:763-771)
• Case reports of psychotic relapse after switching from atypicals to aripiprazole
• Other late stage partial agonist: bifeprunox (D2 and 5HT1a partial agonist)
Site Activity ResultPresynaptic (autoreceptor) agonist ↓DA release
Postsynaptic antagonist ↓ DA signalling
agonist (-) agonist (+)antagonist (+) antagonist (-)
impulse
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Treatment of schizophrenia• Emergency management• The first few weeks/choice of antipsychotic• Side effects• Longer term use and switching• Early lack of response• Maintenance• Managing relapse
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Emergency Management
• Aggressive, agitated patients– Reassurance; reduce stimulation; provide structure– Try to diagnose initially
• Note: you may medicate acutely psychotic and aggressive patient before diagnostic workup.
– If IM drug treatment needed:• Haloperidol 2-5mg plus lorazepam 2mg • Olanzapine (10mg IM; can repeat hourly)• Ziprasidone 10-20mg IM; 40mg/24h• Lorazepam alone IM (1-3mg/hr)
– Diagnostic and medical workup ASAP afterwards
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The first few weeks of treatment• Issues
– choice of initial drug - typical vs atypical– balance speed of response with side-effect liability
• Initial Drug:– Use atypical compounds over (e.g.) haloperidol
• (+)fewer EPSE; (?+)improved patient acceptance due to better tolerability;
– No proven differences in speed of response with any compounds– Titrate dose based on response/side effects– Most patients will respond to initial treatment
• Olanzapine 10-30mg/day• Amisulpride 800-1200mg/day • Risperidone 3-6mg/day (higher doses not more effective)
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SGAs are not created the same - relative efficacy of SGAs vs pooled FGAs
FGA
FGA
FGA
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Management of Side Effects - General
• Important: helps maximise chances that patients will comply with treatment – poor tolerability is a leading cause for treatment failure due to non-compliance
• Is dose appropriate for patient?– lower doses may be needed by elderly, patients with reduced renal/hepatic function, etc– ? Overexposure due to slower metabolism (genetic - CYP2D6 poor metabolizer; patients co-
administered inhibitors of CYP2D6 or -3A4)
• Consider:– is an intervention needed?– temporary/permanent dose reduction – slower titration to final dose– switch to alternative class– use of additional medication to treat side effects
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Management of Specific Side Effects
Mechanism Symptom Management
DA blockade Parkinsonism;akathisia;dystonia
Anticholinergic (biperiden, trihexyphenidyl, procyclidine,benztropine, etc; IV or IM for dystonia); propranolol forakathisia; decrease dose of neuroleptic
Tardivedyskinesia
Prevention (2nd Gen have lower incidence); dose reduce ordiscontinue antipsychotic; ?clozapine and ?other atypicals
NeurolepticMalignantSyndrome
Emergency; stop neuroleptic; BDZs; supportive Rx; ?dantrolene
α1-antagonism
Dizziness/hypotension
Dose reduce; change to amisulpride/quetiapine/ziprasidone
Histamineantagonism
Weight gain Diet; change drug to amisulpride/ziprasidone/aripiprazoleSedation Dose reduce; change to amisulpride/risperidone
Acetylcholineantagonism
Blurred vision Dose reduce; change to risperidone/ziprasidone/AMI/ARI
Constipation Stool softener; fibre+Dry mouth Sugarless gum
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Longer term use and switching…CATIE studyClinical Antipsychotic Trials of Intervention Effectiveness; NEJM 2005, 353:1209
• Prospective randomized blinded comparison of up to 18 months Rx with olanzapine, risperidone, quetiapine, ziprasidone and perphenazine in schizophrenia. NIMH funded.
• Outcome measures: – % discontinuing treatment– Time to discontinuation– Reasons for discontinuation (inefficacy, tolerability issues)– Psychopathology measures (PANSS and CGI)
• Population: – Well matched for demographics, illness characteristics across groups
Olanzapine Quetiapine Risperidone Perphenazine Ziprasidone
n 336 337 341 261 185
Mean modal dose (mg) 20.1 543.4 3.9 20.8 112.8
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CATIE study (2)• No differences in SAEs, suicides/attempts, EPSE, akathisia across groups• Significant advantage for olanzapine in rate of response on PANSS, CGI
Olanzapine Quetiapine Risperidone Perphenazine Ziprasidone
% discontinued 64 82 74 75 79
Median (95% CI) time to discontinuation (months)
9.2(6.9-12.1)
4.6(3.9-5.5)
4.8(4.0-6.1)
5.6(4.5-6.3)
3.5(3.1-5.4)
D/C – lack of efficacy (%) 15 28 27 25 24
D/C – intolerability (%) 19 15 10 16 15
D/C – pt’s decision (%) 24 33 30 30 34
Risk of rehospitalization 0.29 0.66 0.45 0.51 0.57
Weight gain (lbs) 9.4 1.1 0.8 -2.0 -1.6
Weight gain/mo. Rx (lb/mo) 2.0 0.5 0.4 -0.2 -0.3
∆ Cholesterol (mg/dL) 9.7 5.3 -2.1 0.5 -9.2
∆ Prolactin (ng/dL) -6.1 -9.3 15.4 0.4 -4.5
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CATIE study (3)
• Most (74%) patients discontinue their antipsychotic medication within 18 months
• Olanzapine was most effective drug overall on multiple measures – Discontinuation rate and time to discontinuation– Rate of rehospitalization– Better initial symptomatic improvement (PANSS, CGI)
• Perphenazine was clinically no different from other atypicals• Olanzapine had worst tolerability profile, mainly relating to metabolic
consequences
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Early lack of response• Poor response early in therapy:
– is diagnosis correct (drug dependence/withdrawal/medical illness/etc)? – is treatment duration too short? – is there toxicity from Rx regimen (side effects; drug interactions etc)?– is antipsychotic dose adequate?– Is the patient taking his/her meds?– Is the patient taking something else (cannabis/Kronic/P/…..)
• Possibilities:– p.r.n. benzodiazepine for acute agitation/disturbance– review ward milieu/circumstances– review antipsychotic dose (NB: excessive dosing may increase toxicity and do
little for psychotic symptoms)– consider changing antipsychotic – consider adding valproate– consider adding lithium– consider ECT
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Maintenance treatment (1)• First episode Rx for 1-2 years; >2 episodes Rx for 5 years (?and longer) • ~75% of patients will relapse within 18 months of stopping antipsychotic therapy
• Low vs regular dose maintenance– higher relapse rates with lower depot fluphenazine doses (biweekly IM)– some benefit in terms of better tolerability
0 20 40 60
Rate of relapse (%)
Kane1983, 1986
Schooler1997
flu 12.5-50flu 2.5-10flu 1.25-5
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Maintenance (2)• Continuous or Intermittent Rx
– is intermittent Rx (at first sign of prodromal symptoms) effective?– relapse rates over 12 months:
0 20 40 60
Rate of relapse (%)
Carpenter 1990
Herz 1991
Jolley 1989-90
Pietzcker 1993
Schooler 1997
Intermittent RxContinuous Rx
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Managing relapse (1)• Check compliance and aggravating factors
– (low motivation/high stress/intolerable side effects/lack of social support to take meds)
– assess need for psychosocial intervention
• If compliant (i.e. breakthrough symptoms while on Rx), consider changing to alternative antipsychotic– higher doses of old drug usually don’t work and have high s/e rates– crossover (switch) approach to avoid withdrawal relapse– base choice of new drug on prior treatments–
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Managing Relapse (2)• If relapse due to planned dose reduction/ discontinuation
– restart patient on original dose regimen
• If noncompliant/uncooperative/no insight, consider depot antipsychotic – once stabilised, determine IM depot dose by (10-15 x oral daily dose)– give once monthly IM
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Use of clozapine• Risk/benefit assessment suggests it should only be used where there is demonstrated treatment resistance;
• Register with Caremark. Get baseline WCC; repeat weekly for first 6 months, monthly thereafter
• Titrate dose from 12.5mg/day up to 300mg/day over 1-2 weeks;
• Caution with concomitant BDZs (risk of respiratory depression);
• Very low/no EPSE, TD;
• Side effects: neutropenia (3%); agranulocytosis (1%); seizures (5% @>600mg/day); weight gain; hypersalivation; tachycardia; orthostatic hypotension; cardiomyopathy; potentially fatal constipation
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Special Subgroups– Psychosis in Parkinson’s Disease
• conventional antipsychotics worsen PD symptoms• try to reduce DA agonist dose• clozapine
– Psychosis in Alzheimer’s disease• patients may be extremely sensitive to anticholinergic/antihistaminic side effects• age-associated pharmacokinetic changes - lower doses• Mortality increased by both FGAs and SGAs (? Mechanism)• Low dose QUET/OLZ (antihistaminic)
– Psychosis in HIV+ patients• extremely sensitive to drug effects; v low doses (